/** \example example.cpp
    This is example code showing you how to use muparserx.

<pre>
               __________                                 ____  ___
    _____  __ _\______   \_____ _______  ______ __________\   \/  /
   /     \|  |  \     ___/\__  \\_  __ \/  ___// __ \_  __ \     / 
  |  Y Y  \  |  /    |     / __ \|  | \/\___ \\  ___/|  | \/     \ 
  |__|_|  /____/|____|    (____  /__|  /____  >\___  >__| /___/\  \
        \/                     \/           \/     \/           \_/
                                       Copyright (C) 2013 Ingo Berg
                                       All rights reserved.

  muparserx - A C++ math parser library with array and string support
  Copyright (c) 2014, Ingo Berg
  All rights reserved.

  Redistribution and use in source and binary forms, with or without 
  modification, are permitted provided that the following conditions are met:

   * Redistributions of source code must retain the above copyright notice, 
     this list of conditions and the following disclaimer.
   * Redistributions in binary form must reproduce the above copyright notice, 
     this list of conditions and the following disclaimer in the documentation 
     and/or other materials provided with the distribution.

  THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND 
  ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED 
  WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 
  IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, 
  INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT 
  NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR 
  PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, 
  WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 
  ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 
  POSSIBILITY OF SUCH DAMAGE.
</pre>
*/

//---------------------------------------------------------------------------
//
//  muparserx 
//
//  example.cpp - Demonstrates how to use muparserx
//
//---------------------------------------------------------------------------

/** \brief This macro will enable mathematical constants like M_PI. */
#define _USE_MATH_DEFINES 

/** \brief Needed to ensure successfull compilation on Unicode systems with MinGW. */
#undef __STRICT_ANSI__

//--- Standard include ------------------------------------------------------
#if defined(_WIN32) 
  // Memory leak dumping
  #if defined(_DEBUG)
    #define _CRTDBG_MAP_ALLOC
    #include <stdlib.h>
    #include <crtdbg.h>
    #define CREATE_LEAKAGE_REPORT
  #endif

  // Needed for windows console UTF-8 support
  #include <fcntl.h>
  #include <io.h>
#endif

#include <cstdlib>
#include <cstring>
#include <ctime>
#include <cstdio>
#include <cmath>
#include <iostream>
#include <limits>
#include <string>
#include <typeinfo>

//--- muparserx framework -------------------------------------------------------------------------
#include "mpParser.h"
#include "mpDefines.h"
#include "mpTest.h"

//--- other includes ------------------------------------------------------------------------------
#include "timer.h"

using namespace std;
using namespace mup;

#if defined(CREATE_LEAKAGE_REPORT)

// Dumping memory leaks in the destructor of the static guard
// guarantees i won't get false positives from the ParserErrorMsg 
// class wich is a singleton with a static instance.
struct DumpLeaks
{
 ~DumpLeaks()
  {
    _CrtDumpMemoryLeaks();
  }
} static LeakDumper;

#endif

const string_type sPrompt = _T("muparserx> ");

//-------------------------------------------------------------------------------------------------
// The following classes will be used to list muParserX variables, constants
// from this console application
//-------------------------------------------------------------------------------------------------

//-------------------------------------------------------------------------------------------------
class FunPrint : public ICallback
{
public:
  FunPrint() : ICallback(cmFUNC, _T("print"), 1) 
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type *a_pArg, int /*a_iArgc*/)
  {
    console() << a_pArg[0].Get()->ToString() << _T("\n");
    *ret = (float_type)0.0;
  }

  virtual const char_type* GetDesc() const
  {
    return _T("");
  }
  
  virtual IToken* Clone() const
  {
    return new FunPrint(*this);
  }
}; // class FunPrint

//-------------------------------------------------------------------------------------------------
class FunTest0 : public ICallback
{
public:
  FunTest0() : ICallback(cmFUNC, _T("test0"), 0) 
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type * /*a_pArg*/, int /*a_iArgc*/)
  {
    *ret = (float_type)0.0;
  }

  virtual const char_type* GetDesc() const
  {
    return _T("");
  }
  
  virtual IToken* Clone() const
  {
    return new FunTest0(*this);
  }
}; // class FunTest0

//-------------------------------------------------------------------------------------------------
class FunListVar : public ICallback
{
public:

  FunListVar() : ICallback(cmFUNC, _T("list_var"), 0) 
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type * /*a_pArg*/, int /*a_iArgc*/)
  {
    ParserXBase &parser = *GetParent();

    console() << _T("\nParser variables:\n");
    console() << _T(  "-----------------\n");

    // Query the used variables (must be done after calc)
    var_maptype vmap = parser.GetVar();
    if (!vmap.size())
    {
      console() << _T("Expression does not contain variables\n");
    }
    else
    {
      var_maptype::iterator item = vmap.begin();
      for (; item!=vmap.end(); ++item)
      {
        // You can dump the token into a stream via the "<<" operator
        console() << _T("  ") << item->first << _T(" =  ") << *(item->second)/* << _T("\n")*/;

        // If you need more specific information cast the token to a variable object
        Variable &v = (Variable&)(*(item->second));
        console() << _T("  (type=\"") << v.GetType() << _T("\"; ptr=0x") << hex << v.GetPtr() << _T(")\n");
      }
    }

    *ret = (int_type)vmap.size();
  }

  virtual const char_type* GetDesc() const
  {
    return _T("list_var() - List all variables of the parser bound to this function and returns the number of defined variables.");
  }

  virtual IToken* Clone() const
  {
    return new FunListVar(*this);
  }
}; // class FunListVar


//-------------------------------------------------------------------------------------------------
class FunListConst : public ICallback
{
public:

  FunListConst() : ICallback(cmFUNC, _T("list_const"), 0) 
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type * /*a_pArg*/, int /*a_iArgc*/)
  {
    ParserXBase &parser = *GetParent();

    console() << _T("\nParser constants:\n");
    console() << _T(  "-----------------\n");

    val_maptype cmap = parser.GetConst();
    if (!cmap.size())
    {
      console() << _T("No constants defined\n");
    }
    else
    {
      val_maptype::iterator item = cmap.begin();
      for (; item!=cmap.end(); ++item)
        console() << _T("  ") << item->first << _T(" =  ") << (Value&)(*(item->second)) << _T("\n");
    }

    *ret = (int_type)cmap.size();
  }

  virtual const char_type* GetDesc() const
  {
    return _T("list_const() - List all constants of the parser bound to this function and returns the number of defined constants.");
  }

  virtual IToken* Clone() const
  {
    return new FunListConst(*this);
  }
}; // class FunListConst


//-------------------------------------------------------------------------------------------------
class FunBenchmark : public ICallback
{
public:
  FunBenchmark() : ICallback(cmFUNC, _T("bench"), 0) 
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type * /*a_pArg*/, int /*a_iArgc*/)
  {
    char outstr[200];
    time_t t = time(nullptr);

    #ifdef _DEBUG
    strftime(outstr, sizeof(outstr), "Result_%Y%m%d_%H%M%S_dbg.txt", localtime(&t));
    #else
    strftime(outstr, sizeof(outstr), "Result_%Y%m%d_%H%M%S_release.txt", localtime(&t));
    #endif

    const char_type* sExpr[] = { 
                                 _T("sin(a)"),
                                 _T("cos(a)"),
                                 _T("tan(a)"),
                                 _T("sqrt(a)"),
                                 _T("(a+b)*3"),
                                 _T("a^2+b^2"),
                                 _T("a^3+b^3"),
                                 _T("a^4+b^4"),
                                 _T("a^5+b^5"),
                                 _T("a*2+b*2"),
                                 _T("-(b^1.1)"),
                                 _T("a + b * c"),
                                 _T("a * b + c"),
                                 _T("a+b*(a+b)"),
                                 _T("(1+b)*(-3)"),
                                 _T("e^log(7*a)"),
                                 _T("10^log(3+b)"),
                                 _T("a+b-e*pi/5^6"),
                                 _T("a^b/e*pi-5+6"),
                                 _T("sin(a)+sin(b)"),
                                 _T("(cos(2.41)/b)"),
                                 _T("-(sin(pi+a)+1)"),
                                 _T("a-(e^(log(7+b)))"),
                                 _T("sin(((a-a)+b)+a)"),
                                 _T("((0.09/a)+2.58)-1.67"),
                                 _T("abs(sin(sqrt(a^2+b^2))*255)"),
                                 _T("abs(sin(sqrt(a*a+b*b))*255)"),
                                 _T("cos(0.90-((cos(b)/2.89)/e)/a)"),
                                 _T("(1*(2*(3*(4*(5*(6*(a+b)))))))"),
                                 _T("abs(sin(sqrt(a^2.1+b^2.1))*255)"),
                                 _T("(1*(2*(3*(4*(5*(6*(7*(a+b))))))))"),
                                 _T("1/(a*sqrt(2*pi))*e^(-0.5*((b-a)/a)^2)"),
                                 _T("1+2-3*4/5^6*(2*(1-5+(3*7^9)*(4+6*7-3)))+12"),
                                 _T("1+b-3*4/5^6*(2*(1-5+(3*7^9)*(4+6*7-3)))+12*a"),
                                 _T("(b+1)*(b+2)*(b+3)*(b+4)*(b+5)*(b+6)*(b+7)*(b+8)*(b+9)*(b+10)*(b+11)*(b+12)"),
                                 _T("(a/((((b+(((e*(((((pi*((((3.45*((pi+a)+pi))+b)+b)*a))+0.68)+e)+a)/a))+a)+b))+b)*a)-pi))"),
                                 _T("(((-9))-e/(((((((pi-(((-7)+(-3)/4/e))))/(((-5))-2)-((pi+(-0))*(sqrt((e+e))*(-8))*(((-pi)+(-pi)-(-9)*(6*5))/(-e)-e))/2)/((((sqrt(2/(-e)+6)-(4-2))+((5/(-2))/(1*(-pi)+3))/8)*pi*((pi/((-2)/(-6)*1*(-1))*(-6)+(-e)))))/((e+(-2)+(-e)*((((-3)*9+(-e)))+(-9)))))))-((((e-7+(((5/pi-(3/1+pi)))))/e)/(-5))/(sqrt((((((1+(-7))))+((((-e)*(-e)))-8))*(-5)/((-e)))*(-6)-((((((-2)-(-9)-(-e)-1)/3))))/(sqrt((8+(e-((-6))+(9*(-9))))*(((3+2-8))*(7+6+(-5))+((0/(-e)*(-pi))+7)))+(((((-e)/e/e)+((-6)*5)*e+(3+(-5)/pi))))+pi))/sqrt((((9))+((((pi))-8+2))+pi))/e*4)*((-5)/(((-pi))*(sqrt(e)))))-(((((((-e)*(e)-pi))/4+(pi)*(-9)))))))+(-pi)"),
                                 0 };



    ParserX  parser;      
    Value a((float_type)1.0);
    Value b((float_type)2.0);
    Value c((float_type)3.0);

    parser.DefineVar(_T("a"),  Variable(&a));
    parser.DefineVar(_T("b"),  Variable(&b));
    parser.DefineVar(_T("c"),  Variable(&c));
    parser.DefineConst(_T("pi"), (float_type)M_PI);
    parser.DefineConst(_T("e"), (float_type)M_E);

    FILE *pFile = fopen(outstr, "w");
    int iCount = 400000;

    #ifdef _DEBUG
    string_type sMode = _T("# debug mode\n");
    #else
    string_type sMode = _T("# release mode\n");
    #endif

    fprintf(pFile, "%s; muParserX V%s\n", sMode.c_str(), ParserXBase::GetVersion().c_str());
    fprintf(pFile, "\"Eqn no.\", \"number\", \"result\", \"time in ms\", \"eval per second\", \"expr\"\n");

    printf("%s", sMode.c_str());
    printf("\"Eqn no.\", \"number\", \"result\", \"time in ms\", \"eval per second\", \"expr\"\n");

    double avg_eval_per_sec = 0;
    int ct=0;
    for (int i=0; sExpr[i]; ++i)
    {
      ct++;
      StartTimer();
      Value val;
      parser.SetExpr(sExpr[i]);

      // implicitely create reverse polish notation
      parser.Eval(); 

      for (int n=0; n<iCount; ++n)
      {
        val = parser.Eval();
      }

      double diff = StopTimer();
      
      double eval_per_sec = (double)iCount*1000.0/diff;
      avg_eval_per_sec += eval_per_sec;

      #if !defined _UNICODE
      fprintf(pFile, "Eqn_%d, %d, %lf, %lf, %lf, %s\n", i, iCount, (double)val.GetFloat(), diff, eval_per_sec, sExpr[i]);
      printf("Eqn_%d, %d, %lf, %lf, %lf, %s\n"        , i, iCount, (double)val.GetFloat(), diff, eval_per_sec, sExpr[i]);
      #else
      fwprintf(pFile, _T("Eqn_%d, %d, %lf, %lf, %lf, %s\n"), i, iCount, (double)val.GetFloat(), diff, eval_per_sec, sExpr[i]);
      wprintf(_T("Eqn_%d, %d, %lf, %lf, %lf, %s\n")        , i, iCount, (double)val.GetFloat(), diff, eval_per_sec, sExpr[i]);
      #endif
    }

    avg_eval_per_sec /= (double)ct;

    fprintf(pFile, "# Eval per s: %ld", (long)avg_eval_per_sec);

    fflush(pFile);
    *ret = (float_type)avg_eval_per_sec;
  }

  virtual const char_type* GetDesc() const
  {
    return _T("bench() - Perform a benchmark with a set of standard functions.");
  }
  
  virtual IToken* Clone() const
  {
    return new FunBenchmark(*this);
  }
}; // class FunBenchmark


//-------------------------------------------------------------------------------------------------
class FunListFunctions : public ICallback
{
public:
  FunListFunctions() : ICallback(cmFUNC, _T("list_fun"), 0) 
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type * /*a_pArg*/, int /*a_iArgc*/)
  {
    ParserXBase &parser = *GetParent();

    console() << _T("\nParser functions:\n");
    console() << _T(  "----------------\n");

    fun_maptype fmap = parser.GetFunDef();
    if (!fmap.size())
    {
      console() << _T("No functions defined\n");
    }
    else
    {
      val_maptype::iterator item = fmap.begin();
      for (; item!=fmap.end(); ++item)
      {
        ICallback *pFun = (ICallback*)item->second.Get();
        console() << pFun->GetDesc() << _T("\n");
      }
    }

    *ret = (int_type)fmap.size();
  }

  virtual const char_type* GetDesc() const
  {
    return _T("list_fun() - List all parser functions and returns the total number of defined functions.");
  }
  
  virtual IToken* Clone() const
  {
    return new FunListFunctions(*this);
  }
}; // class FunListFunctions


//-------------------------------------------------------------------------------------------------
class FunEnableOptimizer : public ICallback
{
public:
  FunEnableOptimizer() : ICallback(cmFUNC, _T("enable_optimizer"), 1) 
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type *a_pArg, int /*a_iArgc*/)
  {
    ParserXBase &parser = *GetParent();
    parser.EnableOptimizer(a_pArg[0]->GetBool());
    *ret = a_pArg[0]->GetBool();
  }
  virtual const char_type* GetDesc() const
  {
    return _T("enable_optimizer(bool) - Enables the parsers built in expression optimizer.");
  }
  
  virtual IToken* Clone() const
  {
    return new FunEnableOptimizer(*this);
  }
}; // class FunListFunctions


//-------------------------------------------------------------------------------------------------
class FunSelfTest : public ICallback
{
public:
  FunSelfTest() : ICallback(cmFUNC, _T("test"), 0) 
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type * /*a_pArg*/, int /*a_iArgc*/)
  {
    ParserXBase::EnableDebugDump(0, 0);
    ParserTester pt;
    pt.Run();
    *ret = (float_type)0.0;
  }

  virtual const char_type* GetDesc() const
  {
    return _T("test() - Runs the unit test of muparserx.");
  }
  
  virtual IToken* Clone() const
  {
    return new FunSelfTest(*this);
  }
}; // class FunSelfTest

//-------------------------------------------------------------------------------------------------
class FunEnableDebugDump : public ICallback
{
public:
  FunEnableDebugDump() : ICallback(cmFUNC, _T("debug"), 2) 
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type *a_pArg, int /*a_iArgc*/)
  {
    ParserXBase::EnableDebugDump(a_pArg[0]->GetBool(), a_pArg[1]->GetBool());
    if (a_pArg[0]->GetBool())
      console() << _T("Bytecode output activated.\n");
    else
      console() << _T("Bytecode output deactivated.\n");

    if (a_pArg[1]->GetBool())
      console() << _T("Stack output activated.\n");
    else
      console() << _T("Stack output deactivated.\n");

      *ret = (float_type)0.0;
  }

  virtual const char_type* GetDesc() const
  {
    return _T("debug(bDumpRPN, bDumpStack) - Enable dumping of RPN and stack content.");
  }
  
  virtual IToken* Clone() const
  {
    return new FunEnableDebugDump(*this);
  }
}; // class FunEnableDebugDump

#if defined(_UNICODE)
//-------------------------------------------------------------------------------------------------
class FunLang : public ICallback
{
public:
  FunLang() : ICallback(cmFUNC, _T("lang"), 1) 
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type *a_pArg, int /*a_iArgc*/)
  {
    string_type sID = a_pArg[0]->GetString();
    if (sID==_T("de"))
    {
      ParserX::ResetErrorMessageProvider(new mup::ParserMessageProviderGerman);
    }
    else if (sID==_T("en"))
    {
      ParserX::ResetErrorMessageProvider(new mup::ParserMessageProviderEnglish);
    }
    else
    {
      console() << _T("Invalid language ID\n");
    }

    *ret = (float_type)0.0;
  }

  virtual const char_type* GetDesc() const
  {
    return _T("lang(sLang) - Set the language of error messages (i.e. \"de\" or \"en\").");
  }
  
  virtual IToken* Clone() const
  {
    return new FunLang(*this);
  }
}; // class FunLang
#endif // #if defined(_UNICODE)

/*
//-------------------------------------------------------------------------------------------------
class FunGeneric : public ICallback
{
public:

  FunGeneric(string_type sIdent, string_type sFunction) 
    :ICallback(cmFUNC, sIdent.c_str()) 
    ,m_parser()
    ,m_vars()
    ,m_val()
  {
    m_parser.SetExpr(sFunction);
    m_vars = m_parser.GetExprVar();
    SetArgc(m_vars.size());

    // Create values for the undefined variables and bind them
    // to the variables
    var_maptype::iterator item = m_vars.begin();
    for (; item!=m_vars.end(); ++item)
    {
      ptr_val_type val(new Value());
      m_val.push_back(val);

      // assign a parser variable
      m_parser.DefineVar(item->second->GetIdent(), Variable(val.Get()));
    }
  }

  virtual ~FunGeneric()
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type *a_pArg, int a_iArgc)
  {
    // Set the variables
    for (std::size_t i=0; i<(std::size_t)a_iArgc; ++i)
    {
      *m_val[i] = *a_pArg[i];
    }

    *ret = m_parser.Eval();
  }

  virtual const char_type* GetDesc() const
  {
    return _T("xxx(...) - Dynamically defined function");
  }
  
  virtual IToken* Clone() const
  {
    return new FunGeneric(*this);
  }

private:

  ParserX m_parser;
  mup::var_maptype m_vars;
  val_vec_type m_val;
}; // class FunGeneric

//---------------------------------------------------------------------------
class FunDefine : public ICallback
{
public:
  FunDefine() : ICallback(cmFUNC, _T("define"), 2) 
  {}

  virtual void Eval(ptr_val_type &ret, const ptr_val_type *a_pArg, int a_iArgc)
  {
    string_type sFun = a_pArg[0]->GetString();
    string_type sDef = a_pArg[1]->GetString();

    ParserXBase &parser = *GetParent();
    parser.DefineFun(new FunGeneric(sFun, sDef));

    *ret = 0;
  }

  virtual const char_type* GetDesc() const
  {
    return _T("define(Function, Definition) - Define a new parser function.");
  }
  
  virtual IToken* Clone() const
  {
    return new FunDefine(*this);
  }
}; // class FunDefine
*/

//---------------------------------------------------------------------------
void Splash()
{
  console() << _T("-------------------------------------------------------------------------\n");
  console() << _T("               __________                                 ____  ___\n");
  console() << _T("    _____  __ _\\______   \\_____ _______  ______ __________\\   \\/  /\n");
  console() << _T("   /     \\|  |  \\     ___/\\__  \\\\_  __ \\/  ___// __ \\_  __ \\     / \n");
  console() << _T("  |  Y Y  \\  |  /    |     / __ \\|  | \\/\\___ \\\\  ___/|  | \\/     \\ \n");
  console() << _T("  |__|_|  /____/|____|    (____  /__|  /____  >\\___  >__| /___/\\  \\\n");
  console() << _T("        \\/                     \\/           \\/     \\/           \\_/\n");
  console() << _T("  Version ") << ParserXBase::GetVersion() << _T("\n");
  console() << _T("  Copyright (C) 2014 Ingo Berg");
  console() << _T("\n\n");
  console() << _T("-------------------------------------------------------------------------\n\n");
  console() << _T( "Build configuration:\n\n");

#if defined(_DEBUG)
  console() << _T("- DEBUG build\n");
#else
  console() << _T("- RELEASE build\n");
#endif

#if defined(_UNICODE)
  console() << _T("- UNICODE build\n");
#else  
  console() << _T("- ASCII build\n");
#endif

#if defined (__GNUC__)
  console() << _T("- compiled with GCC Version ") << __GNUC__ << "." << __GNUC_MINOR__ << "." << __GNUC_PATCHLEVEL__ << _T("\n");
#elif defined(_MSC_VER)
  console() << _T("- compiled with MSC Version ") << _MSC_VER << _T("\n");
#endif

  console() << _T("- IEEE 754 (IEC 559) is ") << ((std::numeric_limits<float_type>::is_iec559) ? _T("available") : _T(" NOT AVAILABLE")) << _T("\n");
  console() << _T("- ") << sizeof(void*)*8 << _T(" bit\n");
  console() << _T("- Floating point type is \"") << typeid(float_type).name()
                                               << _T("\" (") << std::numeric_limits<float_type>::digits10 << _T(" Digits)")
                                               << _T("\n");
  
  console() << _T("\n");
}

//---------------------------------------------------------------------------
void SelfTest()
{
  console() << _T("-------------------------------------------------------------------------\n\n");
  console() << _T( "Running test suite:\n\n");

  ParserTester pt;
  pt.Run();

  console() << _T("-------------------------------------------------------------------------\n\n");
  console() << _T("Special parser functions:\n");
  console() << _T("  list_var()   - list parser variables and return the number of variables.\n");
  console() << _T("  list_fun()   - list parser functions and return  the number of functions\n");
  console() << _T("  list_const() - list all numeric parser constants\n");
  console() << _T("Command line commands:\n");
  console() << _T("  exprvar      - list all variables found in the last expression\n");
  console() << _T("  rpn          - Dump reverse polish notation of the current expression\n");
  console() << _T("  quit         - exits the parser\n");
  console() << _T("Constants:\n");
  console() << _T("  \"e\"   2.718281828459045235360287\n");
  console() << _T("  \"pi\"  3.141592653589793238462643\n");
  console() << _T("-------------------------------------------------------------------------\n\n");
}

//---------------------------------------------------------------------------
void ListExprVar(ParserXBase &parser)
{
  console() << _T("\nVariables found in : \"") << parser.GetExpr() << _T("\"\n");
  console() << _T(  "-----------------------------\n");

  // Query the used variables (must be done after calc)
  var_maptype vmap = parser.GetExprVar();
  if (!vmap.size())
  {
    console() << _T("Expression does not contain variables\n");
  }
  else
  {
    var_maptype::iterator item = vmap.begin();
    for (; item!=vmap.end(); ++item)
      console() << _T("  ") << item->first << _T(" =  ") << (Variable&)(*(item->second)) << _T("\n");
  }
}

//---------------------------------------------------------------------------
/** \brief Check for external keywords.
*/
int CheckKeywords(const char_type *a_szLine, ParserXBase &a_Parser)
{
  string_type sLine(a_szLine);

  if (sLine==_T("quit"))
  {
    return -1;
  }
  else if (sLine==_T("exprvar"))
  {
    ListExprVar(a_Parser);
    return 1;
  }
  else if (sLine==_T("rpn"))
  {
    a_Parser.DumpRPN();
    return 1;
  }

  return 0;
}

//---------------------------------------------------------------------------
void Calc()
{
//  ParserX  parser(pckALL_NON_COMPLEX);
  ParserX  parser(pckALL_COMPLEX);

  // Create an array variable
  Value arr1(3, 0);
  arr1.At(0) = (float_type)1.0;
  arr1.At(1) = (float_type)2.0;
  arr1.At(2) = (float_type)3.0;

  Value arr2(3, 0);
  arr2.At(0) = (float_type)4.0;
  arr2.At(1) = (float_type)3.0;
  arr2.At(2) = (float_type)2.0;

  Value arr3(4, 0);
  arr3.At(0) = (float_type)1.0;
  arr3.At(1) = (float_type)2.0;
  arr3.At(2) = (float_type)3.0;
  arr3.At(3) = (float_type)4.0;

  Value arr4(3, 0);
  arr4.At(0) = (float_type)4.0;
  arr4.At(1) = false;
  arr4.At(2) = _T("hallo");

  // Create a 3x3 matrix with zero elements
  Value m1(3, 3, 0);
  m1.At(0, 0) = 1;
  m1.At(1, 1) = 1;
  m1.At(2, 2) = 1;

  Value m2(3, 3, 0);
  m2.At(0, 0) = 1;
  m2.At(0, 1) = 2;
  m2.At(0, 2) = 3;
  m2.At(1, 0) = 4;
  m2.At(1, 1) = 5;
  m2.At(1, 2) = 6;
  m2.At(2, 0) = 7;
  m2.At(2, 1) = 8;
  m2.At(2, 2) = 9;

  Value val[5];
  val[0] = (float_type)1.1;
  val[1] = 1;
  val[2] = false;
  val[3] = _T("Hello");
  val[4] = _T("World");

  Value fVal[3];
  fVal[0] = (float_type)1.11;
  fVal[1] = (float_type)2.22;
  fVal[2] = (float_type)3.33;

  Value iVal[3];
  iVal[0] = 1;
  iVal[1] = 2;
  iVal[2] = 3;

  Value sVal[3];
  sVal[0] = _T("hello");
  sVal[1] = _T("world");
  sVal[2] = _T("test");

  Value cVal[3];
  cVal[0] = mup::cmplx_type(1, 1);
  cVal[1] = mup::cmplx_type(2, 2);
  cVal[2] = mup::cmplx_type(3, 3);

  Value ans;
  parser.DefineVar(_T("ans"), Variable(&ans));

  // some tests for vectors
  parser.DefineVar(_T("va"), Variable(&arr1));
  parser.DefineVar(_T("vb"), Variable(&arr2));
  parser.DefineVar(_T("vc"), Variable(&arr3));
  parser.DefineVar(_T("vd"), Variable(&arr4));
  parser.DefineVar(_T("m1"), Variable(&m1));
  parser.DefineVar(_T("m2"), Variable(&m2));

  parser.DefineVar(_T("a"),  Variable(&fVal[0]));
  parser.DefineVar(_T("b"),  Variable(&fVal[1]));
  parser.DefineVar(_T("c"),  Variable(&fVal[2]));

  parser.DefineVar(_T("ia"), Variable(&iVal[0]));
  parser.DefineVar(_T("ib"), Variable(&iVal[1]));
  parser.DefineVar(_T("ic"), Variable(&iVal[2]));

  parser.DefineVar(_T("ca"), Variable(&cVal[0]));
  parser.DefineVar(_T("cb"), Variable(&cVal[1]));
  parser.DefineVar(_T("cc"), Variable(&cVal[2]));

  parser.DefineVar(_T("sa"), Variable(&sVal[0]));
  parser.DefineVar(_T("sb"), Variable(&sVal[1]));

  // Add functions for inspecting the parser properties
  parser.DefineFun(new FunListVar);
  parser.DefineFun(new FunListFunctions);
  parser.DefineFun(new FunListConst);
  parser.DefineFun(new FunBenchmark);
  parser.DefineFun(new FunEnableOptimizer);
  parser.DefineFun(new FunSelfTest);
  parser.DefineFun(new FunEnableDebugDump);
  parser.DefineFun(new FunTest0);
  parser.DefineFun(new FunPrint);

#if defined(_UNICODE)
  parser.DefineFun(new FunLang);
#endif
 
  parser.EnableAutoCreateVar(true);

#ifdef _DEBUG
//  ParserXBase::EnableDebugDump(1, 0);
#endif

  Value x = 1;
  Value y = std::complex<double>(0,1);
  parser.DefineVar(_T("x"), Variable(&x));
  parser.DefineVar(_T("y"), Variable(&y));

  for(;;)
  {
    try
    {
      console() << sPrompt;

      string_type sLine;
      std::getline(mup::console_in(), sLine);

      if (sLine==_T("dbg"))
      {
        sLine   = _T("sin(10*{3+1i,2+0.18}[0])");
        mup::console() << sLine << endl;
      }

      switch(CheckKeywords(sLine.c_str(), parser)) 
      {
      case  0: break;
      case  1: continue;
      case -1: return;
      }
    
      parser.SetExpr(sLine);

      // The returned result is of type Value, value is a Variant like
      // type that can be either a boolean an integer or a floating point value
      ans = parser.Eval();
      {
        // Value supports C++ streaming like this:
        console() << _T("Result (type: '") << ans.GetType() <<  _T("'):\n");
        console() << _T("ans = ") << ans << _T("\n");
/*
        // Or if you need the specific type use this:
        switch (ans.GetType())
        {
        case 's': { std::string s = ans.GetString();               console() << s << " (string)"  << "\n"; } break;
        case 'i': { int i = ans.GetInteger();                      console() << i << " (int)"     << "\n"; } break;
        case 'f': { float_type f = ans.GetFloat();                 console() << f << " (float)"   << "\n"; } break;
        case 'c': { std::complex<float_type> c = ans.GetComplex(); console() << c << " (complex)" << "\n"; } break;
        case 'b': break;
        }
*/
      }
    }
    catch(ParserError &e)
    {
      if (e.GetPos()!=-1)
      {
        string_type sMarker;
        sMarker.insert(0, sPrompt.size() + e.GetPos(), ' ');
        sMarker += _T("^\n");
        console() << sMarker;
      }

      console() << e.GetMsg() << _T(" (Errc: ") << std::dec << e.GetCode() << _T(")") << _T("\n\n");

      //if (e.GetContext().Ident.length()) 
      //  console() << _T("Ident.: ") << e.GetContext().Ident << _T("\n");

      //if (e.GetToken().length()) 
      //  console() << _T("Token: \"") << e.GetToken() << _T("\"\n");
    } // try / catch
  } // for (;;)
}

//---------------------------------------------------------------------------
int main(int /*argc*/, char** /*argv*/)
{
  Splash();
  SelfTest();

#if defined(_UNICODE)

  #if _MSC_VER
    // Set console to utf-8 mode, if this is not done language specific
    // characters will be rendered incorrectly
    if (_setmode(_fileno(stdout), _O_U8TEXT)==-1)
      throw std::runtime_error("Can't set \"stdout\" to UTF-8");
  #endif

  //// Internationalization requires UNICODE as translations do contain non ASCII 
  //// Characters.
  //ParserX::ResetErrorMessageProvider(new mup::ParserMessageProviderGerman);
#endif

  try
  {
    Calc();
  }
  catch(ParserError &e)
  {
    // Only erros raised during the initialization will end up here
    // expression related errors are treated in Calc()
    console() << _T("Initialization error:  ") << e.GetMsg() << endl;
  }
  catch(std::runtime_error &)
  {
    console() << _T("aborting...") << endl;
  }
  
#ifdef MUP_LEAKAGE_REPORT  
  IToken::LeakageReport();  
#endif

  return 0;
}

